FR3115322A1 - Fan blade with zero dihedral at the head - Google Patents

Abstract

The present invention relates to a fan blade (3) made of composite material for a turbomachine. On a portion (15) of the blade (7) which extends from a lower limit (16) located at a predetermined distance (d) from the shank (6) of the blade at least equal to 80% of the predetermined height (h) up to the top (11) of the blade (7), a dihedral angle (D) measured at at least one predefined point on the chord of the blade (3), located on the chord of the blade (3) at the level of the upstream end (13a) of the nose (13) of the shield (12), is greater than or equal to -3° and less than or equal to 0°. Figure for the abstract: Fig. 1

Description

Fan blade with zero dihedral at the head

FIELD OF THE INVENTION

The invention generally relates to the field of turbomachines, and more particularly that of the fan blades of these turbomachines and their method of manufacture.

The invention applies more particularly to fan blades made of composite material and their interaction with the inlet of the primary stream.

STATE OF THE ART

Turbomachine blades, and in particular fan blades, undergo significant mechanical and thermal stresses and must meet strict weight and bulk conditions. It has therefore been proposed to use blades comprising aerodynamic blades made of a composite material comprising a fibrous reinforcement densified by a polymer matrix, which are lighter compared to metal blades with equivalent propulsive characteristics and which have resistance to satisfying heat.

In order to stiffen them and protect them, in particular during an impact from an element ingested in the turbomachine such as a bird, the blades made of composite material generally comprise an attached metal shield fixed to the leading edge of the pale. The shield comprises, in a manner known per se, a solid nose configured to face the leading edge of the blade and two fins configured to cover part of the intrados wall and the extrados wall of the blade.

During the certification and life of an engine, fan blades are subject to ingestion by birds and hailstones. However, depending on the type of object impacting the blade (and in particular its size, its mass) and depending on the type of fan (rotation speed and number of blades), the preferred areas of initiation and propagation of damage are different. The mechanical behavior of fan blades is therefore optimized during the blade design phase to comply with certification rules.

In particular, in the case of large diameter fans such as the fans of turbomachines with a very high bypass ratio ("Ultra High Bypass Ratio" in English, UHBR) comprising at most 20 fan blades, during the ingestion of medium-sized birds), damage is likely to appear at the blade tip and the shield's extrados fin can turn around and locally block the aerodynamic flow. However, such blocking of the aerodynamic flow has the consequence of reducing the thrust that can be achieved by the turbomachine. However, current safety requirements are that a turbomachine must be able, despite an impact from an object, to provide 75% of its thrust at takeoff.

It has therefore been proposed to reduce the length of the fins, in order to reduce the blocking surface of the aerodynamic flow in the event of reversal of the extrados fin. However, when medium-sized birds are ingested, the downstream edge of the fins tends to pinch the composite material structure of the blade, which then tends to be damaged. Thus, to limit this pinching, it is therefore preferable to increase the length of the fins so that their edge is opposite a thicker part of the composite material structure. However, this implies an increase in the blocking surface of the aerodynamic flow in the event of flipping of the fins.

One object of the invention is to provide a fan blade and a fan for a turbomachine, in particular a fan of large diameter and comprising at most twenty fan blades, which guarantees the capacity of the fan to ensure at least 75 % of its take-off thrust despite a medium-sized bird strike.

Another object of the invention is to provide a fan blade and a fan for a turbomachine, in particular a fan of large diameter and comprising at most twenty fan blades having an optimized aero-mechanical compromise.

For this purpose, according to a first aspect of the invention, a fan blade of a turbomachine is proposed comprising:
- a composite material structure comprising a fibrous reinforcement obtained by three-dimensional weaving and a matrix in which the fibrous reinforcement is embedded, the composite material structure comprising a blade with an aerodynamic profile capable of extending in an air flow comprising an edge leading edge and a trailing edge, a root configured to be attached to a fan disk, and a stub extending between the root and the blade, the blade having a predetermined height between the stub and a tip of the blade according to a stacking axis; And
- a metal shield, attached and fixed on the leading edge of the blade, the metal shield comprising a nose fixed on the leading edge.

Furthermore, a blade chord is defined, in a plane normal to the stacking axis, between an upstream end of the nose of the shield and the trailing edge, and on a portion of the blade which extends from a lower limit located at a predetermined distance from the stilt at least equal to 80% of the predetermined height to the tip of the blade, a dihedral angle measured at at least one predefined point on the blade chord, located on the blade chord at the level of the upstream end of the nose of the shield, is greater than or equal to - 3° and less than or equal to 0°.

Certain preferred but non-limiting characteristics of the fan blade according to the first aspect are the following, taken individually or in combination:
- the nose and the fins of the shield together delimit a cavity housing the leading edge of the blade and the predefined point of the chord is located within the cavity;
- the dihedral angle is greater than or equal to -3° and less than or equal to 0° at several predefined points of the blade chord within the portion of the blade;
- within the portion, the dihedral angle is greater than or equal to - 3° and less than or equal to 0° over a distance at least equal to 10% of the predetermined height, preferably over a distance at least equal to 15% of the predetermined height;
- within the portion, the dihedral angle is greater than or equal to -3° and less than or equal to 0° over the entire height of the portion 15;
- within the portion, a variation in the dihedral angle along the stacking axis over a distance equal to 10% of the height of the blade is at most equal to 3°;
- within the portion, the dihedral angle is greater than or equal to -2° and less than or equal to 0°, preferably greater than or equal to -1° and less than or equal to 0°; and or
- the fins extend over a length greater than or equal to 15% and less than or equal to 25% of a chord length of the blade.

According to a second aspect, the invention proposes a fan for a turbomachine comprising a plurality of fan blades according to the first aspect.

Optionally, the fan comprises at most twenty fan blades and/or has an external diameter of the fan of between eighty inches and one hundred inches, preferably between eighty inches and ninety inches.

According to a third aspect, the invention proposes a turbomachine comprising a fan according to the second aspect.

Optionally, the turbomachine has a dilution ratio greater than or equal to 10, for example between 10 and 80 inclusive.

According to a fourth aspect, the invention proposes an aircraft comprising at least one turbomachine conforming to the third aspect.

DESCRIPTION OF FIGURES

Other characteristics, objects and advantages of the invention will emerge from the description which follows, which is purely illustrative and not limiting, and which must be read in conjunction with the appended drawings in which:

There schematically illustrates a blade according to a first embodiment of the invention.

There is a partial couple view of the front of the blade according to one embodiment of the invention.

There is a schematic view of a fan rotor including blades in accordance with one embodiment of the invention, represented in section along a plane perpendicular to the axis of revolution of the fan.

There is a sectional view of the blade according to one embodiment of the invention, according to a plane which is on the one hand parallel to the axis of rotation of the fan and on the other hand perpendicular to a direction in which d dawn extends radially.

There is a schematic perspective view of the fan rotor having blades according to the invention.

There is a schematic view of an aircraft comprising a turbine engine comprising a fan provided with blades according to the invention.

In all the figures, similar elements bear identical references.

DETAILED DESCRIPTION OF THE INVENTION

In the present application, the upstream and the downstream are defined with respect to the normal flow direction of the gas in the fan 1 through the turbomachine. Furthermore, the axis of revolution of the fan 1 turbomachine is called the axis X of radial symmetry of the fan 1. The axial direction corresponds to the direction of the axis X of the fan 1, and a radial direction is a direction perpendicular to this axis and passing through it. Finally, we will use internal and external, respectively, in reference to a radial direction so that the internal part or face of an element is closer to the X axis than the external part or face of the same element.

A turbomachine fan 1 comprises a fan disc 2 carrying a plurality of fan blades 3, associated where appropriate with inter-blade platforms.

The invention applies in a privileged manner to a fan comprising at most twenty blades 3 in a turbine engine with a very high bypass ratio, that is to say whose bypass ratio is greater than or equal to 10, for example between 10 and 80 inclusive, for example more precisely 12 or 14 or 20 or greater than 20. standard atmosphere (as defined by the International Civil Aviation Organization (ICAO) manual, Doc 7488/3, 3rd edition) and at sea level.

Each blade 3 comprises a composite material structure comprising a fibrous reinforcement 4 obtained by three-dimensional weaving and a matrix in which the fibrous reinforcement 4 is embedded. . The foot 5 is intended to allow the attachment of the blade to the fan disk 2 and extends for this purpose between a bottom of a cavity formed in the disk 2 and the outlet of the cavities of the cavity. The blade 7 with its aerodynamic profile is suitable for being placed in an air flow, when the turbomachine is in operation, in order to generate lift. Finally, the stilt 6 corresponds to the zone of the blade 7 which extends between the foot 5 and the blade 7, that is to say between the outlet of the bearing surfaces of the disc 2 and the inter-blade platforms.

The blade 7 also comprises, in a manner known per se, a leading edge 8, a trailing edge 9, an intrados wall and an extrados wall. The leading edge 8 is configured to extend opposite the flow of gases entering the turbomachine. It corresponds to the anterior part of an aerodynamic profile which faces the airflow and which divides the airflow into an underside flow and an underside flow. The trailing edge 9 for its part corresponds to the rear part of the aerodynamic profile, where the intrados and extrados flows meet.

The blade 3 also includes a metal shield 12, attached and fixed to the leading edge 8 of the blade. In a manner known per se, the shield 12 comprises a solid nose 13, fixed to the leading edge 8, an intrados fin 14 and an extrados fin 14 plated and fixed to the intrados wall and the extrados wall of the blade 7, respectively . The shield 12 can in particular be fixed by gluing. The shield 12 can for example be made of a titanium alloy.

Finally, the structure is formed of a plurality of blade sections 3 stacked from the root 5 in the direction of the apex 11 along a stacking axis Z extending radially with respect to the axis of revolution X of the fan 1 A tangential stacking law of the blade then corresponds to the position of the center of gravity of each section of the blade in a plane normal to the stacking axis Z, with respect to this stacking axis Z.

More precisely, the stacking of the blade sections 7 can be defined by the sag and dihedral angles. These angles measure the differences in the directions between the flow and the blades, in projection respectively in a radial and axial plane and an axial and tangent plane to the direction of rotation of the turbomachine. Reference may in particular be made to the document by Leroy H. Smith et al. "Sweep and Dihedral Effects in Axial-Flow Turbomachinery", September 1963, Journal of Basic Engineering , 401-414, for a more complete definition of sag angle and dihedral D-angle.

If the flow is purely axial, which is generally the case at the inlet of the machine, and if we consider for the example a fixed blading with a constant setting on its height, the deflection angle expresses the inclination of the blade in the axial direction, and the dihedral angle D, the inclination of the blade in the tangential direction. A negative sign of the deflection angle expresses an inclination towards the upstream, and a positive sign, towards the downstream; and a negative sign of the dihedral angle D expresses an inclination towards the intrados, and a positive sign, towards the extrados. Inclinations are defined from outward radial directions.

In what follows, “height” will designate a distance along the stacking axis Z.

Thus, the blade 7 has a predetermined height h corresponding to the distance along the stacking axis Z between its lower limit 10, at the intersection with the stilt 6, and its top 11. The predetermined height h of the blade 7 can for example be measured at the intersection between the leading edge 8 and the lower limit 10 of the blade 7.

The blade 3 also has a chord (fictitious straight line segment) defined, in a plane normal to the stacking axis Z, between an upstream end 13a of the nose 13 of the shield 12 and the trailing edge 9. In practice , the upstream end 13a of the nose 13 corresponds to the leading edge of the blade 3, that is to say the upstream part of the shield 12 which actually divides the air flow into a lower surface flow and in an extrados flow. The leading edge 8 of the blade 7 meanwhile extends inside the shield 12, opposite the nose 13, in the extension of its upstream end 13a.

In order to improve the resistance of the fan blade 3 to impacts (in particular to medium-sized birds), within a portion 15 of the blade 3 which extends from a lower limit 16 located at a predetermined distance of the stilt 6 at least equal to 80% of the predetermined height h up to the top 11 of the blade 7, a dihedral angle D (schematized at and at the ) measured at at least one predefined point on the chord of blade 3 is greater than or equal to −3° and less than or equal to 0°. In one embodiment, within the portion 15, the dihedral angle D is greater than or equal to -3° and less than or equal to 0° over a distance at least equal to 10% of the predetermined height, preferably over a distance at least equal to 15% of the predetermined height. In one embodiment, the dihedral angle D is greater than or equal to −3° and less than or equal to 0° over the entire height of the portion 15: in other words, in this embodiment, the dihedral angle D is greater than or equal to −3° and less than or equal to 0° in each section of the blade 3, that is to say at the level of at least one predefined point P of each chord C over the entire height of the portion 15, between 80% and 100% of the height h.

In this way, in the event of detachment of the extrados fin 14, the shape of the blade 3 at the level of this portion 15 tends to press the extrados fin 14 against the extrados wall of the blade 7 under the effect of the centrifugal forces. Indeed, in this portion 15 of the blade 3, the blade 3 is slightly inclined towards the lower surface, which counters the centrifugal forces applied to the upper surface wall.

Preferably, the point of the chord at the level of which the dihedral angle D is measured is located at the level of the shield 12, that is to say within the cavity of the shield 12 which houses the leading edge and which is delimited by the nose 13 and the fins 14 of the shield 12.

As a variant, the point of the chord can extend at the level of the upstream end 13a of the nose 13 of the shield 12, that is to say at the level of the leading edge of the blade 3. This position of the point of the chord has the advantage of simplifying the measurement and checking of the dihedral angle D at the level of the portion 15, while guaranteeing that the portion 15 of the blade 3 is slightly inclined towards the lower surface and avoids the reversal of the fin 14.

In one embodiment, within this portion 15 of the blade 3, the dihedral angle D is greater than or equal to −3° and less than or equal to 0° at several points of the chord.

In one embodiment, in this portion 15 of the blade 3, the dihedral angle D is closest to 0° while remaining negative. Thus, in one embodiment, the dihedral angle D is preferably greater than or equal to -2°, typically greater than or equal to -1°, and less than or equal to 0°.

Thanks to the configuration of the blade 3 in the portion 15, the intrados and extrados fins 14 of the shield 12 can be lengthened in comparison with the prior art, thus reducing the risks of pinching of the fibrous reinforcement 4 in the event of ingestion ( the fibrous reinforcement 4 being thicker at a distance from the leading edge 8). Typically, at least at the portion 15 and over the entire height of this portion 15, the intrados and extrados fins 14 extend over a length greater than or equal to 15% and less than or equal to 25% of the chord length of the blade. By chord of the blade, we will understand here the segment connecting the leading edge 8 and the trailing edge 7, in a plane normal to the stacking axis Z. By chord length, we will understand the length of this segment. By length of a fin 14, we will understand here the projection of this fin 14 on the chord in the plane normal to the Z axis.

In one embodiment, the fan 1 has an outer diameter of between eighty inches (203.2 centimeters) and one hundred inches (254.0 centimeters), preferably between eighty inches (203.2 centimeters) and ninety inches ( 228.6 centimeters).

The fibrous reinforcement 4 can be formed from a fibrous preform in one piece obtained by three-dimensional or multilayer weaving with varying thickness. It comprises warp and weft strands which may in particular comprise carbon, glass, basalt and/or aramid fibres. The matrix for its part is typically a polymer matrix, for example epoxy, bismaleimide or polyimide. The blade 3 is then formed by molding by means of a resin vacuum injection process of the RTM type (for "Resin Transfer Moulding), or else VARRTM (for Vacuum Resin Transfer Molding).

Claims (13)

Blade (3) of fan (1) of a turbomachine comprising:
a composite material structure comprising a fibrous reinforcement (4) obtained by three-dimensional weaving and a matrix in which the fibrous reinforcement (4) is embedded, the composite material structure comprising a blade (7) with an aerodynamic profile able to extend in an airflow comprising a leading edge (8) and a trailing edge (9), a leg (5) configured to be attached to a fan disc (2) (1) and a stilt (6) s extending between the foot (5) and the blade (7), the blade (7) having a predetermined height (h) between the stilt (6) and a top (11) of the blade (7) along an axis d stack (Z); And
a metal shield (12), attached and fixed to the leading edge (8) of the blade (7), the metal shield (12) comprising a nose (13) fixed to the leading edge (8);
a blade chord (3) being defined, in a plane normal to the stacking axis (Z), between an upstream end (13a) of the nose (13) of the shield (12) and the trailing edge ( 9);
the blade (3) of the fan (1) being characterized in that, on a portion (15) of the blade (7) which extends from a lower limit (16) located at a predetermined distance (d) from the stilt (6) at least equal to 80% of the predetermined height (h) up to the top (11) of the blade (7), a dihedral angle (D) measured at at least one predefined point on the rope of the blade (3), located on the chord of the blade (3) at the level of the upstream end (13a) of the nose (13) of the shield (12), is greater than or equal to - 3° and less than or equal to 0°. Fan blade (3) (1) according to Claim 1, in which the nose (13) and the fins (14) of the shield (12) together delimit a cavity housing the leading edge (8) of the blade and the predefined point of the chord is located within the cavity. Blade (3) according to one of Claims 1 or 2, in which the dihedral angle (D) is greater than or equal to - 3° and less than or equal to 0° at several predefined points on the chord of the blade (3) within the portion (15) of the blade (7). Blade (3) according to one of Claims 1 to 3, in which, within the portion (15), the dihedral angle (D) is greater than or equal to - 3° and less than or equal to 0° on a distance at least equal to 10% of the predetermined height, preferably over a distance at least equal to 15% of the predetermined height. Blade (3) according to one of Claims 1 to 4, in which, within the portion (15), the dihedral angle (D) is greater than or equal to - 3° and less than or equal to 0° on the full height of portion 15. Blade (3) according to one of Claims 1 to 5, in which, within the portion (15), a variation of the dihedral angle (D) along the stacking axis over a distance equal at 10% of the height (h) of the blade (7) is at most equal to 3°. Fan blade (3) (1) according to one of Claims 1 to 6, in which, within the portion (15), the dihedral angle (D) is greater than or equal to -2° and less than or equal to 0°, preferably greater than or equal to -1° and less than or equal to 0°. Fan blade (3) (1) according to one of Claims 1 to 7, in which the fins (14) extend over a length greater than or equal to 15% and less than or equal to 25% of a length of blade chord (7). Fan (1) for a turbomachine comprising a plurality of fan (1) blades (3) according to one of Claims 1 to 8. Fan (1) according to Claim 9, comprising at most twenty blades (3) of the fan (1). Fan (1) according to one of claims 9 or 10 having an external diameter of the fan (1) is between eighty inches (203.2 centimeters) and one hundred inches (254.0 centimeters), preferably between eighty inches ( 203.2 centimeters) and ninety inches (228.6 centimeters). Turbomachine (17) comprising a fan (1) according to one of claims 9 to 11. Turbomachine (17) according to claim 12 having a dilution rate greater than or equal to 10, for example between 10 and 80 inclusive.